Abstract
G protein-coupled receptors (GPCRs) are among the most promising drug targets. They often form homo- and heterodimers with allosteric cross-talk between receptor entities, which contributes to fine-tuning of transmembrane signaling. Specifically controlling the activity of GPCR dimers with ligands is a good approach to clarify their physiological roles and validate them as drug targets. Here, we examined the mode of action of positive allosteric modulators (PAMs) that bind at the interface of the transmembrane domains of the heterodimeric GABAB receptor. Our site-directed mutagenesis results show that mutations of this interface impact the function of the three PAMs tested. The data support the inference that they act at the active interface between both transmembrane domains, the binding site involving residues of the TM6s of the GABAB1 and the GABAB2 subunit. Importantly, the agonist activity of these PAMs involves a key region in the central core of the GABAB2 transmembrane domain, which also controls the constitutive activity of the GABAB receptor. This region corresponds to the sodium ion binding site in class A GPCRs that controls the basal state of the receptors. Overall, these data reveal the possibility of developing allosteric compounds able to specifically modulate the activity of GPCR homo- and heterodimers by acting at their transmembrane interface.
Highlights
G protein-coupled receptors (GPCRs) are key players in intercellular communication
The binding site of both rac-BHFF (Kim et al, 2020; Mao et al, 2020) and GS39783 (Shaye et al, 2020) in the purified full-length GABAB receptor was recently reported from structural analyses, including when the receptor is in complex with the G protein (Shen et al, 2021)
The strong agonist effect of rac-BHFF was revealed by its capacity to activate the GABAB receptor even in the absence of GABAB is activated by -aminobutyric acid (GABA)
Summary
G protein-coupled receptors (GPCRs) are key players in intercellular communication. They are involved in many physiological functions (Heng, Aubel, & Fussenegger, 2013), and many mutations (Schoneberg & Liebscher, 2021) and genetic variants (Hauser et al, 2018) of GPCR genes are associated with human diseases. GPCRs are able to activate G proteins in a monomeric state, they can form homo-and heteromers (Ferre et al, 2014), even in native tissues (Albizu et al, 2010; Rivero-Muller et al, 2010), often named homo- and heterodimer for simplicity. Such complexes allow allosteric cross-talk between receptors and contribute to a fine tuning of transmembrane (TM) signaling. Modulating the activity of GPCR dimers could offer a new way of controlling physiological functions
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